In this article, we examined theoretically the role of human cerebral glycogen in buffering the metabolic requirement of a 360-second brain stimulation, expanding our previous modeling study of neurometabolic coupling. We found that glycogen synthesis and degradation affects the relative amount of glucose taken up by neurons versus astrocytes. Under conditions of 175:115mmol/L (similar to 1.5:1) neuronal versus astrocytic activation-induced Na(+) influx ratio, similar to 12% of astrocytic glycogen is mobilized. This results in the rapid increase of intracellular glucose-6-phosphate level on stimulation and nearly 40% mean decrease of glucose flow through hexokinase (HK) in astrocytes via product inhibition. The suppression of astrocytic glucose phosphorylation, in turn, favors the channeling of glucose from interstitium to nearby activated neurons, without a critical effect on the concurrent intercellular lactate trafficking. Under conditions of increased neuronal versus astrocytic activation-induced Na(+) influx ratio to 190:65mmol/L (similar to 3:1), glycogen is not significantly degraded and blood glucose is primarily taken up by neurons. These results support a role for astrocytic glycogen in preserving extracellular glucose for neuronal utilization, rather than providing lactate to neurons as is commonly accepted by the current 'thinking paradigm'. This might be critical in subcellular domains during functional conditions associated with fast energetic demands. Journal of Cerebral Blood Flow & Metabolism (2010) 30, 1895-1904; doi:10.1038/jcbfm.2010.151; published online 8 September 2010

Glycogenolysis in astrocytes supports blood-borne glucose channeling not glycogen-derived lactate shuttling to neurons: evidence from mathematical modeling / Mauro, Dinuzzo; Silvia, Mangia; Maraviglia, Bruno; Giove, Federico. - In: JOURNAL OF CEREBRAL BLOOD FLOW AND METABOLISM. - ISSN 0271-678X. - STAMPA. - 30:12(2010), pp. 1895-1904. [10.1038/jcbfm.2010.151]

Glycogenolysis in astrocytes supports blood-borne glucose channeling not glycogen-derived lactate shuttling to neurons: evidence from mathematical modeling

MARAVIGLIA, Bruno;GIOVE, FEDERICO
2010

Abstract

In this article, we examined theoretically the role of human cerebral glycogen in buffering the metabolic requirement of a 360-second brain stimulation, expanding our previous modeling study of neurometabolic coupling. We found that glycogen synthesis and degradation affects the relative amount of glucose taken up by neurons versus astrocytes. Under conditions of 175:115mmol/L (similar to 1.5:1) neuronal versus astrocytic activation-induced Na(+) influx ratio, similar to 12% of astrocytic glycogen is mobilized. This results in the rapid increase of intracellular glucose-6-phosphate level on stimulation and nearly 40% mean decrease of glucose flow through hexokinase (HK) in astrocytes via product inhibition. The suppression of astrocytic glucose phosphorylation, in turn, favors the channeling of glucose from interstitium to nearby activated neurons, without a critical effect on the concurrent intercellular lactate trafficking. Under conditions of increased neuronal versus astrocytic activation-induced Na(+) influx ratio to 190:65mmol/L (similar to 3:1), glycogen is not significantly degraded and blood glucose is primarily taken up by neurons. These results support a role for astrocytic glycogen in preserving extracellular glucose for neuronal utilization, rather than providing lactate to neurons as is commonly accepted by the current 'thinking paradigm'. This might be critical in subcellular domains during functional conditions associated with fast energetic demands. Journal of Cerebral Blood Flow & Metabolism (2010) 30, 1895-1904; doi:10.1038/jcbfm.2010.151; published online 8 September 2010
2010
brain glycogen; lactate shuttle; mathematical modeling; neurometabolic coupling; neuronal activation
01 Pubblicazione su rivista::01a Articolo in rivista
Glycogenolysis in astrocytes supports blood-borne glucose channeling not glycogen-derived lactate shuttling to neurons: evidence from mathematical modeling / Mauro, Dinuzzo; Silvia, Mangia; Maraviglia, Bruno; Giove, Federico. - In: JOURNAL OF CEREBRAL BLOOD FLOW AND METABOLISM. - ISSN 0271-678X. - STAMPA. - 30:12(2010), pp. 1895-1904. [10.1038/jcbfm.2010.151]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/446764
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